水盐胁迫下根系提水作用对土壤盐分与番茄产量的影响

为探究水盐胁迫下番茄根系发生提水作用的可能性及其对土壤盐分分布和番茄产量的影响,利用上下桶分根装置,设定上桶不同水分(W1、W2、W3表示土壤含水率为田间持水率的60%～70%、50%～60%、40%～50%)和盐分条件(S0、S1、S2表示Na Cl添加量分别为干土质量的0、0.2%、0.4%),监测分析了水盐胁迫下根系提水量、上桶盐分分布及番茄产量。结果表明:随着生育期的推进,根系提水量呈现先增加后减小的趋势,其中盐分对番茄根系提水量影响显著,在相同水分处理条件下,盐分含量越高,根系提水量越大;水盐胁迫下,上桶盐分含量与根系提水量呈线性正相关,除W1S0处理外,上桶土壤电导率在提水量达到最大时有所增加;与对照处理W1S0相比,水盐抑制了根系生长,使根系活性显著下降,同一水分处理下,随着盐分的增加,根长、根表面积及根体积减小;盐分对番茄水分生产率有显著影响,在相同水分条件下,盐分越大,水分生产率越大,7种处理中W2S2水分生产率达到最大,而其产量较对照并未显著减小,生育期提水量占需水量的17.73%。本研究对进一步理解作物在"上干下湿"的土壤水盐胁迫下充分利用土壤剖面深层水分来维持上层根系生存和提高水分生产率具有科学价值。     

成品油管道水击超前保护优化方案

成品油管道发生泵站意外停电事故后通常执行水击超前保护程序,该保护方案对管道的安全性有决定性影响。为了确保管道从事故前稳态安全平稳过渡到事故后较优的运行状态,需要制定最佳的水击超前保护方案。对成品油管道泵站意外停电水击工况进行分析,以水击事故发生后下一稳态时输量最大且各调节阀节流压力之和最小为目标,建立优化模型,相应的约束条件为全线不超压、不汽化。模型求解采取两种不同策略:事故站下游以各站出站压力最低为目标分别寻优,采用水力坡降线平移法求解;事故站上游以整体总节流最小寻优,为了提高求解速度,采用深度优先搜索法求解。以某成品油管道泵站意外停电事故工况为例,对该优化模型进行实例应用,并根据优化结果制定水击事故过渡过程的控制逻辑,并使用仿真软件SPS验证了控制逻辑的合理性,表明该优化模型合理可靠。     

大型喷杆喷雾机钟摆式主被动悬架自适应鲁棒控制研究

针对大型喷雾机喷杆钟摆式主被动悬架系统存在的参数不确定性和随机干扰导致控制精度低、稳定性差的问题，对基于模型补偿的自适应鲁棒控制算法进行研究。建立了钟摆式主被动悬架的非线性动力学模型和调节机构几何方程，基于模型设计了自适应鲁棒控制器，综合悬架系统和电液位置伺服系统模型中存在的参数不确定性，同时兼顾系统未补偿的摩擦力和外部扰动等不确定非线性因素，通过理论分析和试验证明，在同时存在模型参数不确定和不确定非线性的情况下，设计的控制器可以保证系统输出跟踪控制的暂态性能和稳态精度。以单出杆液压作动器驱动的28m大型喷杆主被动悬架为例，借助建立的大型喷杆悬架半实物仿真平台进行了控制算法的试验验证，并使用Stewart六自由度运动平台模拟底盘的运动干扰，与反馈线性化控制器、鲁棒反馈控制器、PID控制器进行了试验对比，结果表明，设计的基于模型补偿的自适应鲁棒控制器最大跟踪误差0.148°，而反馈线性化控制器最大跟踪误差0.201°，鲁棒反馈控制器最大跟踪误差0.51°，PID控制器最大跟踪误差0.48°。设计的控制器在同时存在参数不确定性和扰动的情况下，使用较小的反馈增益能够保证渐进跟踪性能和稳态跟踪精度。     

过滤后养猪废水厌氧发酵与固氮技术研究

为探究养殖废水高效处理方法,文章采用粉碎玉米秸秆过滤养殖废水中悬浮性固体,并对过滤后养猪废水作厌氧发酵和固氮研究。经过滤,总固体(TS)去除率达47.55%,在中温(35±2)℃条件下,研究5、15、25 d 3种不同水力停留时间(HRT),过滤后养猪废水全混合厌氧发酵特性。厌氧发酵过程运行稳定,产生沼气甲烷含量均稳定在70%左右,当水力停留时间为15 d时,产甲烷效率为239.17 mL CH4/gVS,溶解性化学需氧量(SCOD)去除率60.94%。沼液采用鸟粪石沉淀法固氮处理,经过试验参数优化在物质的量比n(Mg2+)n(PO43-):n(NH4+)=1.021.061、pH为9.6条件下,氨氮(TAN)去除率达86.66%,处理后沼液中氨氮浓度为160 mg·L-1,研究结果可为养猪废水资源化利用提供参考。     

Low soil temperature reducing the yield of drip irrigated rice in arid area by influencing anther development and pollination

Drip irrigation can produce high rice yields with significant water savings; therefore, it is widely used in arid area water-scarce northern China. However, high-frequency irrigation of drip irrigation with low temperature well water leads to low root zone temperature and significantly reduce the rice yield compared to normal temperature water irrigated rice, for example, reservoir water. The main purpose of this paper is to investigate the effects of low soil temperature on the yield reduction of drip irrigated rice in the spike differentiation stage. The experiment set the soil temperatures at 18°C, 24°C and 30°C under two irrigation methods(flood and drip irrigation), respectively. The results showed that, at the 30°C soil temperature, drip irrigation increased total root length by 53% but reduced root water conductivity by 9% compared with flood irrigation. Drip irrigation also increased leaf abscisic acid and proline concentrations by 13% and 5%, respectively. These results indicated that drip irrigated rice was under mild water stress. In the 18°C soil temperature, drip irrigation reduced hydraulic conductivity by 58%, leaf water potential by 40% and leaf net photosynthesis by 25% compared with flood irrigation. The starch concentration in male gametes was also 30% less in the drip irrigation treatment than in the flood irrigation treatment at soil temperature 18°C. Therefore, the main reason for the yield reduction of drip irrigated rice was that the low temperature aggravates the physiological drought of rice and leads to the decrease of starch content in male gametes and low pollination fertilization rate. Low temperature aggravates physiological water deficit in drip irrigated rice and leads to lower starch content in male gametes and low pollination fertilization rate, which is the main reason for the reduced yield of drip irrigated rice. Overall, the results indicated that the low soil temperatures aggravated the water stress that rice was under in the drip irrigated environment, causing declines both in the starch content of male gametes and in pollination rate. Low temperature will ultimately affect the rice yield under drip irrigation.     

高效节能水锤泵技术研究进展

为了厘清水锤泵的技术发展动态和目前的技术应用现状,文中回顾了水锤泵技术发展历史,并简要介绍了水锤泵的基本结构,在此基础上,阐述了水锤泵的效率计算方法,并对水锤泵的理论设计方法发展进行了梳理.随后对水锤泵的国内外研发现状进行了大致概括,提出了中国水锤泵发展受限的根本原因,并指出简化制造和装配工艺、发展大型化水锤泵制造技术以及研发轻型化和分体式水锤泵是未来发展的重点.接着总结出水锤泵系统参数和结构参数是影响水锤泵的主要因素.最后对国内外水锤泵的实际应用现状进行了对比分析,提出发展应用水锤泵应在考虑泄水阀和输水阀动态启闭过程的水锤泵运行全过程理论模型的基础上发展适用于不同群体或目标的水锤泵制造技术.研究成果对扩大水锤泵的应用范围,提升中国水锤泵的制造技术提供了一定的参考.     

Cattle manure and inorganic nitrogen fertilizer application effects on soil hydraulic properties and maize yield of two soils of Murewa district,Zimbabwe

This study set out to determine the effects of cattle manure and inorganic N‐fertilizer application on the hydraulic properties and maize yield of a clay and sandy soil in a smallholder farming area of Zimbabwe. Four fields classified as homefields (HF: more fertile and closer to homesteads) and outfields (OF: less fertile and further from the homesteads) were selected on clay and sandy soil. They were subjected to four treatments, control (no fertility amendment), 5, 15 and 25 t/ha cattle manure + 100 kg/ha N (as ammonium nitrate) for 7 years. A two‐way randomized complete block design was used with fertility and field type as the two factors. Clay soil hydraulic properties, which included density of macropores with a diameter >300 μm, unsaturated hydraulic conductivity, steady‐state infiltration rate, moisture retention under low suction and maize grain yield, were significantly improved (P < 0.05) by fertility management compared with the control and were generally comparable between the HF and OF. Fertility management significantly improved maize grain yield on sandy soils but did not enhance hydraulic parameters, thereby indicating poor responsiveness in structural build‐up. On the other hand, significantly different hydraulic parameters between the sandy soil HF and OF suggested effects of other factors not related to soil fertility and field type treatments. We therefore concluded that application of a high rate (25 t/ha) of cattle manure and inorganic N‐fertilizer is beneficial for fertility restoration to the degraded OFs with associated comparable hydraulic properties on HFs and OFs on clay soil, unlike on sandy soil.     

剪枝机液压缸缸体有限元分析

建立了剪枝机液压缸缸体的有限元力学模型，通过有限元分析得出液压缸缸体的危险点位置，为液压缸缸体的设计和计算提供了理论依据。     

Tillage Effects on Crop Yield and Physicochemical Properties of Sodic Soils

Tillage modifies soil structure and has been suggested as a practice to improve physical, hydrological and chemical properties of compacted soils. But little is known about effect of long‐term tillage on physicochemical soil properties and crop yield on sodic soils in India. Our objective was to investigate the effect of different tillage regimes on crop yield (wheat and paddy rice) and physicochemical properties of sodic soils. Two sodic sites under conventional tillage for 5 (5‐YT; 5‐year tillage) and 9 (9‐YT; 9‐year tillage) years were selected for this study. Changes in crop yield and physicochemical soil properties were compared with a control, sodic land without any till history, that is, 0‐year tillage/untilled (0‐YT). Five replicated samples at 0‐ to 10‐cm and 10‐ to 20‐cm soils depths were analysed from each site. In the top, 0‐ to 10‐cm soil depth 5‐YT and 9‐YT sites had higher particle density (Pd), porosity, water holding capacity, hydraulic conductivity, organic carbon, total nitrogen (N_t), available nitrogen (N_avail), phosphorus (P_avail) and exchangeable calcium (Exch. Ca⁺⁺) than 0‐YT, whereas bulk density (Bd), C : N ratio and CaCO₃ were significantly lower. Bd, pH, EC and CaCO₃ increased significantly with depth in all the lands, whereas Pd, porosity, water holding capacity, hydraulic conductivity, organic carbon, N_t, N_avail, P_avail and Exch. Ca⁺⁺ decreased. We conclude that continuous tillage and cropping can be useful for physical and chemical restoration of sodic soils. Copyright © 2014 John Wiley & Sons, Ltd.     

基于电液比例技术的摩擦焊机液压系统设计

根据摩擦焊工艺的要求,设计了石油钻杆摩擦焊机液压系统.该系统采用电液比例技术实现压力的闭环控制;采用双液压泵结构来满足不同阶段对流量的不同要求.经实际应用效果良好.